Smoking article wrapper and method of making same

Patent 4915118 Issued on April 10, 1990. Estimated Expiration Date:

April 20, 2008. Estimated Expiration Date is calculated based on simple USPTO term provisions. It does not account for terminal disclaimers, term adjustments, failure to pay maintenance fees, or other factors which might affect the term of a patent.

Abstract Claims Description Full Text

Patent References

Wrapper for smoking articles containing magnesium oxide
Patent #: 4231377
Issued on: 11/04/1980
Inventor: Cline , et al.

Wrapper for smoking articles and method
Patent #: 4420002
Issued on: 12/13/1983
Inventor: Cline

Wrapper for smoking articles and method
Patent #: 4433697
Issued on: 02/28/1984
Inventor: Cline , et al.

Wrapper for smoking articles and method Patent #: 4450847
Issued on: 05/29/1984
Inventor: Owens

Inventors

Assignee

P. H. Glatfelter Company

Application

No. 183988 filed on 04/20/1988

US Classes:

131/365, Wrapper or binder162/139Cigarette paper

Examiners

Primary: Millin, V.

Attorney, Agent or Firm

Kerkam, Stowell, Kondracki & Clarke

International Class

A24D 001/02

Description

This invention relates to a smoking article wrapper which when provided with a suitable tobacco column produces up to 75% less particulate sidestream smoke than do cigarettes fabricated with conventionalcigarette paper wrappers and to methods of producing same.

BACKGROUND OF THE INVENTION

It has been the endeavor of the industry to reduce visible sidestream smoke which most non-smokers consider to be irritating and offensive. Some of the patents dealing with sidestream are as follows.

U.S. Pat. No. 4,231,377, to W. K. Cline and R. H. Martin is directed to a cellulosic wrapper for a tobacco charge which contains at least 15% magnesium oxide and at least 0.5% of a chemical adjuvant selected from alkali metal acetates,carbonates, citrates, nitrates, and tartrates. Both a smoking product and the method of smoking product preparation are disclosed. Furthermore, the patent discloses that magnesium oxide, as referred to in the patent, includes its hydrate, magnesiumhydroxide, and mixtures of magnesium oxide and magnesium hydroxide.

U.S. Pat. No. 4,420,002, to W. K. Cline is directed to a cellulosic wrapper for a tobacco charge which contains 5% to 50% magnesium hydroxide filler having a median particle size less than 10 micrometers and an unreactive magnesium oxidefiller. In addition, this patent discloses that best results are achieved by adding the magnesium hydroxide filler to the fiber pulp furnish to achieve an intimate contact between filler and fibers. Both a smoking product and the method of smokingproduct preparation are described.

U.S. Pat. No. 4,433,697, to W. K. Cline and W. F Owens is directed to a cellulosic wrapper for a smoking article which contains 1% to 5% of a ceramic fiber plus magnesium hydroxide and/or magnesium oxide fillers. The ceramic fibers wereselected from a group consisting of polycrystalline alumina, aluminum silicate, and amorphous alumina. Furthermore, this patent discloses that the addition of ceramic fiber provides a more solid ash and even greater sidestream smoke reduction than theprior art. Again, both a smoking product and the method of smoking product preparation are disclosed.

U.S. Pat. No. 4,450,847 to W. F. Owens is directed to a cellulosic wrapper containing amorphous magnesium hydroxide gel freshly precipitated on the fibers of the sheet as a filler, plus unreactive magnesium oxide, calcium carbonate or both asco-filler(s). Furthermore, this patent specifically discloses a wrapper with 2% to 8% by weight of potassium acetate as a chemical adjuvant. A key disclosure in the patent pertains to the physical characteristics of an "amorphous gel of magnesiumhydroxide" and the manner in which deposition of said gel on the fiber or paper provides more intimate contact and complete coverage of the paper fibers during in situ precipitation. In addition to the wrapper, itself, both a smoking product and themethod of smoking product preparation are disclosed.

In a co-pending concurrently filed application by R. H. Martin, there is disclosed a cellulosic wrapper containing up to 15% precipitated magnesium hydroxide filler, up to 25% particulate magnesium hydroxide filler, 0% to 10% calcium carbonatefiller, and up to 5% by weight of sodium and potassium acetate burning chemicals. Furthermore, the optimum median particle size of the particulate magnesium hydroxide is a relatively large 15 micrometers. This large particle size would not be expectedby "one skilled in the art". A reduction in sidestream particulate delivery rate of up to 80% is disclosed. A cigarette which exhibits a 70% or greater reduction in sidestream particulate smoke is perceived by an observer as producing little, if any,sidestream smoke during static burning.

BRIEF DESCRIPTION OF THE INVENTION

The purpose of this invention is to provide a cigarette paper with good appearance and high opacity which when fabricated into a cigarette with a suitable tobacco column statically burns at an optimum rate and produces up to 75% less particulatesidestream smoke than do cigarettes fabricated with conventional cigarette paper wrappers. More specifically, these desirable physical and smoking characteristics are accomplished by incorporating high levels of freshly precipitated magnesium hydroxidefiller which is prepared by a controlled precipitation reaction producing hard, granular, fast-settling magnesium hydroxide particles. In addition, particulate magnesium hydroxide and calcium carbonate co-fillers may be employed to optimize desiredburning and sidestream smoke properties.

DETAILED DESCRIPTION OF THE INVENTION

In the specification and claims the words "freshly precipitated magnesium hydroxide" means using the precipitate before any appreciable agglomeration takes place.

Based on the prior art described above, there has been developed two low sidestream cigarette paper products. The first a commercial product, disclosed in U.S. Pat. No. 4,450,847 which consistently provides a nominal 50% reduction insidestream particulate delivery rate as compared to 2.1. -.0.1 mg/min for a conventional cigarette. This paper product contains 12% to 15% in situ precipitated magnesium hydroxide filler, 28% to 25% calcium carbonate filler and approximately 4% byweight of potassium and sodium acetate burning chemicals. The second, a developmental product, contains precipitated magnesium hydroxide, particulate magnesium hydroxide, and calcium carbonate fillers and 4% to 5% potassium and sodium acetate burningchemicals. The preferred particulate magnesium hydroxide filler has the relatively large median particle size of 15 micrometers. This product is disclosed and claimed in co-pending application of R. H. Martin filed even date herewith.

While the product of the said R. H. Martin application meets and even exceeds sidestream smoke reduction requirements; three specific properties are less than optimum, e.g., (1) low sheet opacity (2) low static burning rate, and (3) marginal ashappearance. All three properties relate to the large particle size of the particulate magnesium hydroxide filler which is partly responsible for the extraordinarily high sidestream smoke reductions. The large magnesium hydroxide filler particles arefar above the optimum particle size for efficient visible light scattering, depress or lower the static burning rate of the sheet by decreasing both heat transfer and peripheral burning cone temperature, and cause less cohesive ash due to the slowercombustion rate and inherent geometric effect. A means of optimizing the three properties cited above without significantly affecting the excellent sidestream reduction properties of this paper is required.

A literature investigation revealed that magnesium hydroxide particle size, slurry viscosity, settling rate, sediment volume, etc. obtained during the precipitation of magnesium hydroxide depend upon the stoichiometric rate of reagent addition,concentration, magnesium salt anion, hydroxide cation, temperature, agitation, etc. These controlling factors are summarily discussed in articles by S. B. Kanungo, P. K. Pe and U. P. Basu, Indian J. Technol. 8 (1970), 23 and by O. Sohnel and J. Maracek,Kristal and Tecknik, 13 (1978), 253. Paramount to control of magnesium hydroxide particle size is the rate of reactant addition, e.g., adding chemical equivalents of hydroxide and magnesium salt together at equal or near equal rates (equivalents/unittime) provides a granular precipitate with a high settling rate and a low sediment volume. This infers that individual magnesium hydroxide particles or aggregates are relatively large, as opposed to the extremely small particles found in highlygelatinous precipitates with very slow settling rates and large sediment volumes. Deviations from exactly equal addition rate conditions for either reactant result in magnesium hydroxide slurries exhibiting higher viscosities, slower settling rates andlarger sediment volumes which is indicative of smaller particles and increasing gel structure formation. In fact, precisely setting the relative addition rate of the two reagents at various values near the equal (1:1 ) stoichiometric rate conditionconstitutes a method of controlling magnesium hydroxide slurry viscosity and consequent particle size. Furthermore, observations have revealed that the type, particle size and amount of "seed" material such as particulate magnesium hydroxide or calciumcarbonate present in the slurry during precipitation influence the final viscosity of the slurry, the resulting paper and its smoking properties. Thus, the magnesium hydroxide particle size can readily be optimized during precipitation by controllingthe variables described above.

This ability to control magnesium hydroxide particle size has proven beneficial in improving the sheet opacity, combustibility and ash appearance of low sidestream cigarette papers containing magnesium hydroxide filler. Freshly precipitatedmagnesium hydroxide with a larger median particle size and essentially neutral charge does not coat the flax fibers as effectively as very small, highly charged magnesium hydroxide particles, thereby increasing combustibility. For this reason all of theprecipitated magnesium hydroxide filler prepared by the previously patented and described process and part or all of the large size particulate magnesium hydroxide filler can be replaced with precipitated magnesium hydroxide from the controlled processwith a resulting net improvement in sheet combustibility. The median particle size of the magnesium hydroxide from the controlled precipitation process actually determines the static burning rate and sidestream particulate delivery rate of the sheet. Sidestream smoke reduction is still quite excellent due to the inherently high activity of freshly precipitated magnesium hydroxide whether large or small particles. Furthermore, the larger precipitated magnesium hydroxide particles improve sheetopacity by providing more efficient light scattering and sheet tensile strength by increasing fiber-to-fiber bonding area.

This invention constitutes a novel means of attaining high magnesium hydroxide filler levels in low sidestream cigarette paper which provides excellent sidestream particulate smoke reduction at normal to high static burning rates. This isaccomplished by employing magnesium hydroxide from a controlled precipitation process which produces granular, fast-settling magnesium hydroxide particles. Precipitated magnesium hydroxide from this controlled process is incorporated as a filler intothe sheet at levels from 2% to 60% by weight along with particulate magnesium hydroxide as a co-filler at levels of 0% to 40% and/or calcium carbonate as a co-filler at levels of 0% to 40%. The preferred wrapper embodying the above filler system is a100% flax pulp sheet weighing 45 g/M², containing a total filler level of 30% to 40% by weight, 20% to 30% of which is freshly precipitated magnesium hydroxide filler from the controlled process, and 10% to 20% of which is calcium carbonateco-filler. Reductions in sidestream particulate delivery rate of 60% to 75% are attained.

EXAMPLE 1

The initial investigation of the above cited concept was an evaluation of precipitation process effects on handsheet combustibility. A variety of reagent addition modes were evaluated and a "worst-case" combustibility model was selected forhandsheet composition. This handsheet contained 15% freshly precipitated magnesium hydroxide filler and 25% particulate magnesium hydroxide co-filler with a 15 micrometer median particle size. This specific handsheet composition has consistentlyexhibited self-extinction during earlier handsheet and smoking studies. Reagent addition mode, pH, viscosity, static burning rate and static sidestream particulate delivery rate are shown below. The stoichiometrically exact number of chemicalequivalents for both reagents was added for each experiment with only the mode of reagent addition being varied.

__________________________________________________________________________ Sidestream Static Particulate Slurry Burning Delivery Handsheet Slurry Viscosity Rate Rate Designation* Reagent Addition Mode pH (cps) (Mg/Min) (Mg/Min) __________________________________________________________________________ VBR 6535 1B Add NaOH to Mg(OAc)₂ 11.26 960 SE SE VBR 6535 2B Add Mg(OAc)₂ to NaOH 9.55 380 SE SE VBR 6535 3B NaOH and Mg(OAc)₂ added 10.05 25 36.1 0.56 together at equal rate VBR 6535 4B NaOH and Mg(OAc)₂ added 10.0 40 SE SE together at equal rate (Cold, 5° C.) VBR 6535 7B Add NaOH and Mg(OAc)₂ 9.82 520 SE SE together with Mg(OAc)₂ added 10% faster VBR 6535 8B Add NaOHand Mg(OAc)₂ 9.67 200 SE SE together with NaOH added 10% faster VBR 6536 10B NaOH and Mg(OAc)₂ 9.50 (90%) 140 (90%) SE SE added together - 9.82 (10%) 375 (10%) 90% NaOH added then final 10% NaOH added VBR 6535 11B NaOH andMg(OAc)₂ 11.73 (90%) 100 (90%) SE SE Added together - 9.68 (10%) 80 (10%) 90% Mg(OAc)₂ added then final 10% Mg(OAc)₂ added __________________________________________________________________________ *Handsheet specifications: 45g/M² basis weight, 40% total filler, 90% flax/10% wood pulp fiber furnish, treated with 8% solution of potassium acetate burning chemical.

The above results are both dramatic and definitive. Only one addition mode furnishes a handsheet which sustains a static burn, i.e., the mode in which the two reagents are combined at equal stoichiometric addition rates under ambient temperatureconditions. The slurry viscosities of the precipitated magnesium hydroxide suspension are likewise dramatic and confirm the unique physical characteristics of magnesium hydroxide precipitated by the equal addition rate method. With the exception of onelow porosity sheet, VBR 6535-1B, porosity exerted little, if any, impact on burning characteristics. Coresta porosity for the series was relatively constant at 24.3. -.4 air permeability units.

EXAMPLE 2

A number of handsheet screening experiments were conducted to determine the effects of high levels of precipitated magnesium hydroxide filler from the equal addition rate process, little or no particulate magnesium hydroxide co-filler andmoderate levels of calcium carbonate co-filler on static burning rate and sidestream particulate delivery rate. All handsheets were prepared from precipitated magnesium hydroxide which was obtained from the equal addition rate process; furthermore,precipitation was conducted in the presence of other co-filler(s). Fiber furnish, level of precipitated magnesium hydroxide filler, level of calcium carbonate filler, slurry viscosity, static burning rate and sidestream particulate delivery rate areshown in the following table.

__________________________________________________________________________ % Static Sidestream Precipitated % Slurry Burning Particulate Handsheet Mg(OH)₂ CaCO₃ Viscosity Rate Delivery Designation* Fiber Furnish FillerFiller (cps) (Mg/Min) Rate (Mg/Min) __________________________________________________________________________ VBR 6535 14B 70% flax/ 20 20 60 54.0 0.81 30% wood pulp VBR 6535 15B 70% flax/ 25 15 75 57.8 0.76 30% wood pulp VBR 6535 13B 80%flax/ 20 20 20 38.3 0.67 20% wood pulp VBR 6535 8B 90% flax/ 25 15 65 49.0 0.58 10% wood pulp VBR 6544 4B 90% flax/ 25** 15 85 41.9 0.62 10% wood pulp VBR 6548 10B 100% flax 25 15 90 42.9 0.61 VBR 6548 12B 100% flax 30 10 45 78.8 0.61 __________________________________________________________________________ *Handsheet Specifications: 45 g/M² basis weight, 40% total filler, treated with an 8% solution of potassium acetate burning chemical **20% precipitated Mg(OH)₂ fillerand 5% particulate Mg(OH)₂ filler (15 micrometer median particle size)

The above data reveal that low sidestream cigarette paper handsheets containing high levels of precipitated magnesium hydroxide filler from the equal addition rate process, little or no particulate magnesium hydroxide co-filler and moderatelevels of calcium carbonate co-filler do indeed result in cigarettes which exhibit moderate to high combustibility and low sidestream particulate delivery rates. Reduction in sidestream particulate delivery rate ranges from 61% to 72% relative to theaverage 2.1 . -.0.1 mg/min delivery rate of conventional commercial cigarettes. The significant increase in static burning rate with increase in precipitated magnesium hydroxide filler from the equal addition rate process is unexpected in view of priorexperience with precipitated magnesium hydroxide from other processes and sources.

EXAMPLE 3

The handsheet screening experiments described above confirmed that high levels of precipitated magnesium hydroxide filler from the equal addition rate process along with only a calcium carbonate co-filler offer low sidestream cigarette papersexhibiting very low sidestream particulate delivery rates coupled with enhanced combustibility. In this handsheet study example, the precipitated magnesium hydroxide and calcium carbonate filler levels are systematically varied in order to define thepreferred filler levels providing the lowest sidestream particulate delivery rate at the optimum static burning rate. The level of precipitated magnesium hydroxide filler from the equal addition rate process, level of calcium carbonate co-filler, slurryviscosity, static burning rate and sidestream particulate delivery rate are shown in the following table.

______________________________________ Sidestream Static Particulate Handsheet % PPT % Viscos- Burning Delivery Designa- Mg(OH)₂ CaCO₃ ity Rate Rate tion* Filler Filler (cps) (mg/min) (mg/min) ______________________________________ 1B 15 25 25 70.8 0.87 2B 20 20 60 52.3 0.75 8B 25 15 65 49.0 0.58 12B 30 10 45 78.8 0.61 3B 35 5 45 108.5 0.93 4B 40 0 160 SE SE ______________________________________ *Handsheet Specifications: 45 g/M²basis weight, 40% total filler, 90% flax/10% wood pulp fiber furnish, treated with an 8% solution of potassium acetate burning chemical.

The results of this study are unequivocal. A distinct minimum in static burning rate is displayed in the precipitated magnesium hydroxide filler level range of 20% to 25%. In the case of the sidestream particulate delivery rate, magnesiumhydroxide filler level range is optimized at 25% to 30%. Thus, optimum smoking characteristics occur at filler levels of 25% precipitated magnesium hydroxide and 15% calcium carbonate. A sheet of this filler composition demonstrates a static burningrate of about 50 mg/min and a sidestream particulate delivery rate of approximately 0.60 mg/min (71% reduction), both totally acceptable values.

EXAMPLE 4

Since a chemical adjuvant, commonly referred to as a burning chemical, is an essential ingredient of low sidestream cigarette papers based on the magnesium hydroxide/oxide filler system in its various permutations, machine-made low sidestreamcigarette paper with precipitated magnesium hydroxide filler from the equal addition rate process and calcium carbonate co-filler was treated with various levels of potassium acetate burning chemical and evaluated for sidestream smoke characteristics.

Machine-made low sidestream cigarette paper from trial RD 99827 run with water on the size press was used for this evaluation. It is a 45g/M² basis weight sheet containing 25% precipitated magnesium hydroxide filler from the equal rateaddition process and 15% calcium carbonate co-filler; the magnesium hydroxide was precipitated in the presence of the calcium carbonate co-filler. This sheet had an average porosity of 19 Coresta and Tappi opacity of 84.2%. This opacity is a dramaticimprovement over the average 70% Tappi opacity value exhibited by machine-made low sidestream cigarette papers with dual particulate/precipitated magnesium hydroxide fillers. Although the RD 99827 paper used in this study was produced with water on thesize press, it still contained about 1.5% to 2.0% by weight of sodium acetate burning chemical which came from the off-line precipitation reaction between magnesium acetate and sodium hydroxide.

Paper from trial RD 99827 was treated with aqueous solutions of 2%, 4%, 6%, 8%, 10% and 12% by weight of potassium acetate burning chemical on a 4"-wide laboratory size press. Cigarettes were prepared from these papers and smoked. Staticburning rates and sidestream particulate delivery rates are shown in the following table.

______________________________________ Sidestream Static Particulate % KOAc Burning Delivery in Sizing Rate Rate Solution (mg/min) (mg/min) ______________________________________ 2 45.2 0.78 4 50.3 0.81 6 52.7 0.77 8 55.0 0.78 10 54.50.82 12 54.1 0.73 ______________________________________

The above date reveal that static burning rate increases regularly from 2% potassium acetate treatment up to the 6% to 8% burning chemical treatment level. From this point on, static burning rate remains essentially constant with increasingburning chemical treatment level. The sidestream particulate delivery rate results are entirely different; the sidestream particulate delivery rate remains essentially constant over the burning chemical treatment range at 0.78. -. 0.04 mg/min. Thus,the results of this experiment indicate that burning chemical level effects static burning rate, but has essentially no effect on sidestream particulate delivery rate.

SUMMARY OF THE INVENTION

Optimum combustion properties and excellent reductions in sidestream particulate delivery rate and yield are achieved by a low sidestream cigarette paper characterized as:

1. Containing cellulosic pulp fibers such as those provided by flax pulp or chemical wood pulp for use in conventional cigarette papers.

2. Having a basis weight between 30 g/M² and 100 g/M^2.

3. Containing freshly precipitated magnesium hydroxide filler from a controlled reaction process, particulate magnesium hydroxide co-filler and/or calcium carbonate co-filler.

4. Containing freshly precipitated magnesium hydroxide filler from a controlled reaction based on reagent addition at equal or near equal stoichiometric addition rates.

5. Containing freshly precipitated magnesium hydroxide filler from a controlled precipitation reaction between a soluble magnesium salt such as the chloride, nitrate, cetate, etc. and a Group IA or IIA hydroxide.

6. Containing freshly precipitated magnesium hydroxide filler precipitated by an equal or near equal stoichiometric addition rate process in the presence of the particulate magnesium hydroxide and/or calcium carbonate co-filler(s) and in theabsence of the cellulosic pulp fibers.

7. Containing freshly precipitated magnesium hydroxide filler from a controlled reaction at a filler level of 2% to 60% by weight in the sheet with 15% to 35% preferred.

8. Containing particulate magnesium hydroxide co-filler at a filler level of 0% to 40% by weight in the sheet with 0% to 25% preferred.

9. Containing particulate magnesium hydroxide filler having a particle size of less than 2 micrometers to 50 micrometers in diameter with a median particle size of 10 to 15 micrometers preferred.

10. Containing calcium carbonate co-filler at a filler level of 0% to 40% by weight in the sheet with 5% to 30% preferred.

11. Containing the chemical adjuvants, or burning chemicals, potassium acetate and sodium acetate separately or in mixtures thereof at levels of 1% to 8% by weight in the sheet with 3% to 5% preferred.

Low sidestream cigarette papers embodying the features described above provide a sheet demonstrating good formation and very high opacity, optimum combustibility and sidestream particulate delivery rates approaching 0.60 mg/min or a 71% reductionrelative to conventional commercial cigarettes.